Image generating apparatus and image generation method

ABSTRACT

A rendering unit renders an object in a virtual space to generate a computer graphics image. An AR superimposing unit superimposes the computer graphics image on a captured image of a reality space to generate an augmented-reality image. A post-processing unit performs post-processing on the augmented-reality image. The AR superimposing unit superimposes, on the same computer graphics image, a plurality of captured images provided at a frame rate higher than the frame rate of the computer graphics image generated by the rendering unit, to generate the augmented-reality image.

TECHNICAL FIELD

The present invention relates to an apparatus and a method that are usedto generate images.

BACKGROUND ART

There are situations where players of a game wear head-mount displaysconnected to games consoles on their heads, and play the game bymanipulating controllers and the like while watching screens displayedon the head-mount displays. Since if users wear a head-mount display,they see nothing other than a video being displayed on the head-mountdisplay, this has the effect of enhancing the sense of immersion intothe world of the video, and making the game more entertaining. Inaddition, when a video of VR (Virtual Reality) is being displayed on ahead-mount display, if a user wearing the head-mount display can view avirtual space in all directions around him/her 360-degrees by turninghis/her head, the sense of immersion into the video is enhanced further,and the manipulability of an application such as a game is alsoimproved.

In addition, although it becomes impossible for a user wearing anon-transparent head-mount display to see the outside world directly,there are video-transparent (video see-through) head-mount displays thatcan capture a video of the outside world by a camera mounted on thehead-mount displays, and display the video on their display panels.Video-transparent head-mount displays also superimpose objects in avirtual world generated by CG (Computer Graphics) on a video of theoutside world captured by a camera, and thereby can generate and displaya video of AR (Augmented Reality). Such an augmented-reality videorepresents the real world which is augmented by virtual objects unlikevirtual reality disconnected from the real world, and users canexperience a virtual world while being aware of a connection with thereal world.

SUMMARY Technical Problems

In a case where augmented-reality videos are displayed on a head-mountdisplay, videos of the outside world are taken in by a camera mounted onthe head-mount display at a high frame rate in conjunction with motionsof the user's head. On the other hand, a virtual world on which thosevideos are superimposed requires a long time for rendering, so that theframe rate of the virtual world is lower than that of the camera.Accordingly, augmented-reality videos cannot be generated in accordancewith the high frame rate of the camera, and a user feels slight delaysin augmented-reality videos, resulting in the loss of the sense ofconnection with the real world. In addition, since the frequency ofpost-processing performed on augmented-reality videos is also the sameas the frequency of rendering, the quality of videos lowers.

The present invention has been made in view of such problems, and anobject thereof is to provide an image generating apparatus and an imagegeneration method that can improve the visual quality of computergraphics.

Solution to Problems

In order to solve the problems, an image generating apparatus in anaspect of the present invention includes: a rendering unit that rendersan object in a virtual space to generate a computer graphics image; anda post-processing unit that performs post-processing on the computergraphics image. The post-processing unit performs the post-processing onthe computer graphics image at a frequency higher than a frame rate atwhich the rendering unit generates the computer graphics image.

Another aspect of the present invention is also an image generatingapparatus. The apparatus includes: a rendering unit that renders anobject in a virtual space to generate a computer graphics image; asuperimposing unit that superimposes the computer graphics image on acaptured image of a reality space to generate an augmented-realityimage; and a post-processing unit that performs post-processing on theaugmented-reality image. The superimposing unit superimposes, on thesame computer graphics image, a plurality of the captured imagesprovided at a frame rate higher than a frame rate of the computergraphics image generated by the rendering unit, to generate theaugmented-reality image.

Still another aspect of the present invention is an image generationmethod. The method includes: a rendering step of rendering an object ina virtual space to generate a computer graphics image; a superimposingstep of superimposing the computer graphics image on a captured image ofa reality space to generate an augmented-reality image; and apost-processing step of performing post-processing on theaugmented-reality image. In the superimposing step, a plurality of thecaptured images provided at a frame rate higher than a frame rate of thecomputer graphics image generated by the rendering unit are superimposedon the same computer graphics image to generate the augmented-realityimage.

Note that any combination of constituent elements explained above, andconfigurations obtained by converting expressions of the presentinvention between methods, apparatuses, systems, computer programs, datastructures, recoding mediums and the like are also valid as aspects ofthe present invention.

Advantageous Effect of Invention

According to the present invention, the visual quality of computergraphics can be improved.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an external-appearance view of a head-mount display.

FIG. 2 is a configuration view of an image generating system accordingto the present embodiment.

FIG. 3 is a functional configuration diagram of the head-mount display.

FIG. 4 is a functional configuration diagram of an image generatingapparatus according to the present embodiment.

FIG. 5 is a figure for explaining the configuration of the imagegenerating system to serve as the premise for superimposing a CG imageon a camera image to generate an augmented-reality image.

FIG. 6 is a figure for explaining a procedure of generating anaugmented-reality image to be performed by the image generating systemin FIG. 5.

FIG. 7 is a figure for explaining the configuration of the imagegenerating system according to the present embodiment for superimposinga CG image on a camera image to generate an augmented-reality image.

FIG. 8 is a figure for explaining a procedure of generating anaugmented-reality image to be performed by the image generating systemin FIG. 7.

DESCRIPTION OF EMBODIMENT

FIG. 1 is an external-appearance view of a head-mount display 100. Thehead-mount display 100 is a display apparatus worn on a user's head inorder for the user to watch still images, moving images or the likedisplayed on the display, and listen to sounds, music or the like outputfrom a headphone.

A gyro sensor, an acceleration sensor or the like built in or externallyattached to the head-mount display 100 enables measurement ofinformation regarding the position of the user's head wearing thehead-mount display 100, and information regarding the orientation of thehead such as the rotation angle or the inclination.

The head-mount display 100 has a camera unit mounted thereon which cancapture images of the outside world while a user is wearing thehead-mount display 100.

The head-mount display 100 is one example of a “wearable display.”Although a method of generating images to be displayed on the head-mountdisplay 100 is explained here, an image generation method of the presentembodiment can be applied not only to cases where the head-mount display100 in its narrow sense is worn, but also to cases where eyeglasses, aneye-glass type display, an eye-glass type camera, a headphone, a headset(a headphone with a microphone), earphones, earrings, an ear-wearablecamera, a hat, a camera-mounted hat, a hairband or the like is worn.

FIG. 2 is a configuration view of an image generating system accordingto the present embodiment. The head-mount display 100 is connected to animage generating apparatus 200 through an interface 300 complying withHDMI (registered trademark) (High-Definition Multimedia Interface) whichis a standard of communication interfaces for transmitting videos andsounds with digital signals or complying with any other standard, forexample.

The image generating apparatus 200 predicts position and orientationinformation regarding the head-mount display 100 taking intoconsideration a delay from generation to display of a video based oncurrent position and orientation information regarding the head-mountdisplay 100, draws an image that should be displayed on the head-mountdisplay 100 on the premise of the predicted position and orientationinformation regarding the head-mount display 100, and transmits theimage to the head-mount display 100.

One example of the image generating apparatus 200 is a games console.The image generating apparatus 200 may further be connected to a servervia a network. In that case, the server may provide, to the imagegenerating apparatus 200, an online application such as a game in whicha plurality of users can participate via networks. The head-mountdisplay 100 may be connected to a computer or a mobile terminal insteadof the image generating apparatus 200.

FIG. 3 is a functional configuration diagram of the head-mount display100.

A control unit 10 is a main processor that processes signals such asimage signals or sensor signals, instructions, or data, and outputs theprocessed signals, instructions, or data. An input interface 20 receivesmanipulation signals or setting signals from a user, and supplies thesignals to the control unit 10. An output interface 30 receives a signalfor an image from the control unit 10, and displays the image on adisplay panel 32.

A communication control unit 40 transmits data input from the controlunit 10 to an external device via a network adapter 42 or an antenna 44by a wired or wireless communication. The communication control unit 40also receives data from an external device and outputs the data to thecontrol unit 10 via the network adapter 42 or the antenna 44 by a wiredor wireless communication.

A storage unit 50 temporarily stores data, parameters, manipulationsignals and the like processed by the control unit 10.

An orientation sensor 64 detects information regarding the position ofthe head-mount display 100, and information regarding the orientation ofthe head-mount display 100 such as the rotation angle or theinclination. The orientation sensor 64 is realized by combining a gyrosensor, an acceleration sensor, an angular-acceleration sensor and thelike as appropriate. Forward/backward, leftward/rightward, andupward/downward motions of the user's head may be detected by using amotion sensor formed by combining at least one of a three-axisterrestrial magnetism sensor, a three-axis acceleration sensor, and athree-axis gyro (angular velocity) sensor.

An external input/output terminal interface 70 is an interface forconnecting a peripheral instrument such as a USB (Universal Serial Bus)controller. An external memory 72 is an external memory such as a flashmemory.

A camera unit 80 includes configurations required for image-capturingsuch as a lens, an image sensor, or a ranging sensor, and supplies acaptured video of the outside world and depth information to the controlunit 10. The control unit 10 controls focusing, zooming and the like ofthe camera unit 80.

An HDMI transmitting/receiving unit 90 transmits and receives digitalsignals of videos and sounds to and from the image generating apparatus200 in accordance with HDMI. The HDMI transmitting/receiving unit 90receives a video of the outside world captured by the camera unit 80 anddepth information from the control unit 10, and transmits the video andthe depth information to the image generating apparatus 200 through anHDMI transmission path. The HDMI transmitting/receiving unit 90 receivesan image generated by the image generating apparatus 200 from the imagegenerating apparatus 200 through the HDMI transmission path, andsupplies the image to the control unit 10.

The control unit 10 can supply data of an image or a text to the outputinterface 30 to cause a display panel 32 to display the image or thetext, and supply the data to the communication control unit 40 to makethe data transmitted to an external device.

Current position and orientation information regarding the head-mountdisplay 100 detected by the orientation sensor 64 is notified to theimage generating apparatus 200 via the communication control unit 40 orthe external input/output terminal interface 70. Alternatively, the HDMItransmitting/receiving unit 90 may transmit the current position andorientation information regarding the head-mount display 100 to theimage generating apparatus 200.

FIG. 4 is a functional configuration diagram of the image generatingapparatus 200 according to the present embodiment. A block diagramfocusing on functions is drawn in the figure, and functional blockstherein can be realized in various forms only by hardware, only bysoftware, or by a combination of hardware and software.

At least some functions of the image generating apparatus 200 may beimplemented by the head-mount display 100. Alternatively, at least somefunctions of the image generating apparatus 200 may be implemented by aserver connected to the image generating apparatus 200 via a network.

A position/orientation acquiring unit 210 acquires current position andorientation information regarding the head-mount display 100 from thehead-mount display 100.

A viewpoint/line-of-sight setting unit 220 uses the position andorientation information regarding the head-mount display 100 acquired bythe position/orientation acquiring unit 210 to set a viewpoint positionand a line-of-sight direction of a user.

An HDMI transmitting/receiving unit 280 receives a video of the realityspace captured by the camera unit 80 from the head-mount display 100,and supplies the video to an image-signal processing unit 250.

The image-signal processing unit 250 performs ISP (Image SignalProcessing) such as RGB conversion (demosaicing), white-balance, colorcorrection, or noise reduction on a Raw image captured by the cameraunit 80 of the head-mount display 100, and furthermore performsdistortion correction processing of removing distortion caused by theoptical system of the camera unit 80, or the like. The image-signalprocessing unit 250 supplies, to an image generating unit 230, the RGBimage having been subjected to the image signal processing and thedistortion correction processing.

The image generating unit 230 reads out data required for generation ofcomputer graphics from an image storage unit 260, renders objects in avirtual space to generate a CG image, superimposes the CG image on acamera image of the reality space provided from the image-signalprocessing unit 250 to thereby generate an augmented-reality image, andoutputs the augmented-reality image to the image storage unit 260.

The image generating unit 230 includes a rendering unit 232, an ARsuperimposing unit 234, a post-processing unit 236, areverse-reprojection unit 238, a reprojection unit 240, and a distortionprocessing unit 242.

The rendering unit 232 renders objects in the virtual space that can beseen from the viewpoint position of a user wearing the head-mountdisplay 100 in the line-of-sight direction of the user in accordancewith the viewpoint position and the line-of-sight direction of the userset by the viewpoint/line-of-sight setting unit 220, and gives therendered objects to the AR superimposing unit 234.

The AR superimposing unit 234 superimposes the CG image generated by therendering unit 232 on a camera image supplied from the image-signalprocessing unit 250 to thereby generate an augmented-reality image, andgives the augmented-reality image to the post-processing unit 236.

The post-processing unit 236 performs post-processing such asdepth-of-field adjustment, tone mapping, or anti-aliasing on theaugmented-reality image, and performs post-processing such that theaugmented-reality image in which virtual objects are superimposed on animage of the reality space looks natural and smooth.

The reprojection unit 240 receives latest position and orientationinformation regarding the head-mount display 100 from theposition/orientation acquiring unit 210, performs reprojectionprocessing on the augmented-reality image having been subjected to thepost-processing, and converts the augmented-reality image into an imageas seen from the latest viewpoint position and in the latestline-of-sight direction of the head-mount display 100.

Here, reprojection is explained. In a case where the head-mount display100 is given a head-tracking function, and a video of a virtual realityis generated while the viewpoint and the line-of-sight direction arebeing changed in conjunction with motions of the user's head, a delayoccurs between generation and display of the video of the virtualreality. As a result, misalignment occurs between the direction of theuser's head used as the premise at the time of generation of the videoand the direction of the user's head at a time point of display of thevideo on the head-mount display 100, and the user may feel as if he/shegot sick (called “VR sickness (Virtual Reality Sickness)” and the like).

In this manner, it takes a long time until a drawn image is output tothe head-mount display 100 after a motion of the head-mount display 100is sensed, a CPU issues an image-drawing command, and a GPU (GraphicsProcessing Unit) executes rendering. It is assumed here thatimage-drawing is performed at the frame rate of 60 fps (frame/second),for example, and a delay corresponding to one frame occurs after amotion of the head-mount display 100 is sensed and until an image isoutput. This is approximately 16.67 milliseconds if the frame rate is 60fps, and is a sufficient time for a human to sense a time lag.

In view of this, a process called “time-warp” or “reprojection” isperformed, and a rendered image is corrected in accordance with a latestposition and a latest orientation of the head-mount display 100 tothereby make it difficult for a human to sense a time lag.

The distortion processing unit 242 performs a process of distorting(distortion) and deforming an image in accordance with a distortioncaused by the optical system of the head-mount display 100 on anaugmented-reality image having been subjected to the reprojectionprocessing, and stores the distorted and deformed image in the imagestorage unit 260.

The HDMI transmitting/receiving unit 280 reads out, from the imagestorage unit 260, frame data of the augmented-reality image generated bythe image generating unit 230, and transmits the frame data to thehead-mount display 100 in accordance with HDMI.

In a case where a camera image captured from a viewpoint position and ina line-of-sight direction at a recent time point is superimposed on a CGimage rendered on the premise of a viewpoint position and aline-of-sight direction at a past time point, it is necessary to performreverse-reprojection processing on the camera image in order to make theviewpoint position and the line-of-sight direction match those of thepast CG image.

The reverse-reprojection unit 238 performs reverse-reprojectionprocessing of converting a camera image supplied from the image-signalprocessing unit 250 back into an image as seen from a past viewpointposition and in a past line-of-sight direction, and gives the processedimage to the AR superimposing unit 234. The AR superimposing unit 234superimposes the CG image as seen from the past viewpoint position andin the past line-of-sight direction generated by the rendering unit 232on the reverse-reprojected camera image to thereby generate anaugmented-reality image, and gives the augmented-reality image to thepost-processing unit 236.

With reference to FIG. 5 and FIG. 6, a premise technique of the presentembodiment is explained, and thereafter with reference to FIG. 7 andFIG. 8, an improved technique of the present embodiment is explained.

FIG. 5 is a figure for explaining the configuration of the imagegenerating system to serve as the premise for superimposing a CG imageon a camera image to generate an augmented-reality image. Here, for easeof explanation, main configurations of the head-mount display 100 andthe image generating apparatus 200 that are for generating anaugmented-reality image are illustrated and explained.

A camera image of the outside world captured by the camera unit 80 ofthe head-mount display 100 is transmitted to the image generatingapparatus 200, and supplied to the image-signal processing unit 250. Theimage-signal processing unit 250 performs the image signal processingand the distortion correction processing on the camera image, and givesthe processed camera image to the AR superimposing unit 234.

The rendering unit 232 of the image generating apparatus 200 generatesvirtual objects as seen from the viewpoint position and in theline-of-sight direction of a user wearing the head-mount display 100,and gives the virtual objects to the AR superimposing unit 234.

The AR superimposing unit 234 superimposes the CG image on the cameraimage, and generates an augmented-reality image. The post-processingunit 236 performs the post-processing on the augmented-reality image.The reprojection unit 240 converts the augmented-reality image havingbeen subjected to the post-processing such that the viewpoint and theline-of-sight direction of the augmented-reality image match a latestviewpoint position and a latest line-of-sight direction. The distortionprocessing unit 242 performs the distortion processing on theaugmented-reality image obtained after the reprojection. An eventual RGBimage obtained after the distortion processing is transmitted to thehead-mount display 100, and displayed on the display panel 32.

FIG. 6 is a figure for explaining a procedure of generating anaugmented-reality image to be performed by the image generating systemin FIG. 5.

The camera unit 80 of the head-mount display 100 captures an image ofthe outside world, and outputs a Raw image (S10). The image-signalprocessing unit 250 performs the image signal processing and thedistortion correction processing on the Raw image captured by the cameraunit 80, and generates a camera image for use in SLAM (SimultaneousLocalization and Mapping) (S12). IMU data indicating current orientationinformation regarding the head-mount display 100 is acquired from an IMU(Inertial Measurement Unit) such as the orientation sensor 64 of thehead-mount display 100 (S14). SLAM processing of simultaneouslyperforming self-localization and environment-mapping is executed byusing the camera image and the IMU data, and the orientation of the userwearing the head-mount display 100 is estimated (S16).

Processes required for an update of computer graphics such as viewpointcomputation or physical calculation for virtual objects are performed onthe basis of orientation estimation data (S18). The rendering unit 232renders objects in a virtual space, and generates a CG image (S20).

Here, it is noted that since a process amount increases depending on thenumber of objects to be displayed in the virtual space, rendering takesa considerably long time if the number of objects is large.

The image-signal processing unit 250 performs the image signalprocessing and the distortion correction processing on the Raw imagecaptured by the camera unit 80, and generates a camera image forproviding a see-through video to the head-mount display 100 (S22).

The AR superimposing unit 234 superimposes the CG image on the cameraimage to thereby generate an augmented-reality image (S24). Thepost-processing unit 236 performs the post-processing on theaugmented-reality image (S26).

It is noted here that since the post-processing is a process on theentire image, it can be performed in a relatively short time as comparedwith the rendering, without being dependent on the number of virtualobjects.

IMU data indicating latest orientation information regarding thehead-mount display 100 is acquired from an inertial measurement unit(S28). The reprojection unit 240 converts the augmented-reality image inaccordance with the latest orientation information regarding thehead-mount display 100 (S30). The distortion processing unit 242performs lens-distortion processing on the augmented-reality image afterthe reprojection, and outputs the augmented-reality image having beensubjected to the lens-distortion processing (S32).

In a case of the configuration and processing procedure of the imagegenerating system explained with reference to FIG. 5 and FIG. 6, cameraimages are superimposed on images in accordance with the frame rate ofthe rendering. Since the rendering takes a long time for processing, theframe rate of the rendering of a virtual space by the rendering unit 232is lower than the frame rate of image-capturing of the reality space bythe camera unit 80. For example, even if image-capturing is performed bythe camera unit 80 at 120 fps, images can be drawn by the rendering onlyat 60 fps in some cases. Accordingly, the frame rate of a see-throughvideo displayed on a display panel of the head-mount display 100 lowersin accordance with the frame rate of the rendering, and the see-throughvideo is interrupted often, resulting in the loss of the sense ofreality even if the augmented-reality video is watched.

In view of this, in the present embodiment, camera images aresuperimposed multiple times on a CG image rendered once, and thepost-processing on the augmented-reality video is performed multipletimes to thereby generate a smooth video according to the frame rate ofthe camera unit 80.

FIG. 7 is a figure for explaining the configuration of the imagegenerating system according to the present embodiment for superimposinga CG image on a camera image to generate an augmented-reality image.Explanations that overlap explanations of the premise technique in FIG.5 are omitted as appropriate, and configurations which are improvementsover the premise technique are explained.

In order to superimpose camera images captured by the camera unit 80multiple times on a CG image which is a result of the renderingperformed by the rendering unit 232 once, the reverse-reprojection unit238 performs reverse-reprojection processing on camera images havingbeen subjected to the image signal processing and the distortioncorrection processing by the image-signal processing unit 250, convertsthe camera images into images as seen from a past viewpoint position andin a past line-of-sight direction of the head-mount display 100, andgives the images obtained through the conversion to the AR superimposingunit 234.

The AR superimposing unit 234 synthesizes a camera image supplied fromthe image-signal processing unit 250 in the first synthesis on a CGimage of a result of the rendering performed by the rendering unit 232once, but synthesizes camera images reverse-reprojected by thereverse-reprojection unit 238 in the second and subsequent synthesis onthe same CG image. The post-processing unit 236 performs thepost-processing on an augmented-reality image obtained through synthesisby the AR superimposing unit 234 in any case. The subsequent processesare the same as those in the premise technique in FIG. 5. Note that itmay be configured such that a camera image reverse-reprojected by thereverse-reprojection unit 238 is synthesized with a rendering result CGimage also in the first synthesis, without distinguishing the firstprocess from the second and subsequent synthesis.

FIG. 8 is a figure for explaining a procedure of generating anaugmented-reality image to be performed by the image generating systemin FIG. 7.

The camera unit 80 of the head-mount display 100 captures an image ofthe outside world, and outputs an (n−1)-th Raw image (S40).

At an n-th timing of Vsync, processes of the following Steps S42 to S62are executed.

The image-signal processing unit 250 performs the image signalprocessing and the distortion correction processing on the (n−1)-th Rawimage captured by the camera unit 80, and generates a camera image foruse in SLAM (S42). IMU data that indicates current orientationinformation regarding the head-mount display 100 is acquired from aninertial measurement unit (S44). SLAM processing is executed by usingthe camera image and the IMU data, and the orientation of the userwearing the head-mount display 100 is estimated (S46).

Processes required for an update of computer graphics such as viewpointcomputation or physical calculation for virtual objects are performed onthe basis of orientation estimation data (S48). The rendering unit 232renders objects in a virtual space, and generates an (n−1)-th CG image(S50).

The image-signal processing unit 250 performs the image signalprocessing and the distortion correction processing on the (n−1)-th Rawimage captured by the camera unit 80, and generates an (n−1)-th cameraimage for providing a see-through video to the head-mount display 100(S52).

The AR superimposing unit 234 superimposes the (n−1)-th CG image on the(n−1)-th camera image to thereby generate an (n−1)-th augmented-realityimage (S54). The post-processing unit 236 performs the post-processingon the (n−1)-th augmented-reality image (S56).

IMU data indicating latest orientation information regarding thehead-mount display 100 is acquired from an inertial measurement unit(S58). The reprojection unit 240 predicts a viewpoint position and aline-of-sight direction of a frame which is two frames ahead on thebasis of the latest orientation information of the head-mount display100, and converts the (n−1)-th augmented-reality image into an (n+1)-thaugmented-reality image (S60). Since a delay corresponding to two framesoccurs due to the rendering, a frame which is two frames ahead ispredicted to perform the reprojection.

The distortion processing unit 242 performs the lens-distortionprocessing on the (n+1)-th augmented-reality image after thereprojection, and outputs the (n+1)-th augmented-reality image havingbeen subjected to the lens-distortion processing at an (n+1)-th timingof Vsync (S62).

Next, at an n-th timing of Vsync, the camera unit 80 of the head-mountdisplay 100 captures an image of the outside world, and outputs an n-thRaw image (S70).

At an (n+1)-th timing of Vsync, processes of the following Steps S72 toS86 are executed.

The image-signal processing unit 250 performs the image signalprocessing and the distortion correction processing on the n-th Rawimage captured by the camera unit 80, and generates an n-th camera imagefor providing a see-through video to the head-mount display 100 (S72).

IMU data indicating latest orientation information regarding thehead-mount display 100 is acquired from an inertial measurement unit(S74). The reverse-reprojection unit 238 converts the n-th camera imageinto the (n−1)-th camera image as seen from a viewpoint position of aprevious frame and in a line-of-sight direction of the previous frame,on the basis of the latest IMU data (S76).

The AR superimposing unit 234 superimposes the (n−1)-th CG imagerendered in Step S50 on the reverse-reprojected (n−1)-th camera image tothereby generate an (n−1)-th augmented-reality image (S78). Thepost-processing unit 236 performs the post-processing on the (n−1)-thaugmented-reality image (S80).

IMU data indicating latest orientation information regarding thehead-mount display 100 is acquired from an inertial measurement unit(S82). The reprojection unit 240 predicts a viewpoint position and aline-of-sight direction of a frame which is three frames ahead on thebasis of the latest orientation information of the head-mount display100, and converts the (n−1)-th augmented-reality image into an (n+2)-thaugmented-reality image (S84). It is noted that since the camera imageis converted back into a camera image of a previous frame by thereverse-reprojection processing, the reprojection processing in Step S84converts the augmented-reality image into an augmented-reality image ofa frame which is three frames ahead.

The distortion processing unit 242 performs the lens-distortionprocessing on the (n+2)-th augmented-reality image after thereprojection, and outputs the (n+2)-th camera image having beensubjected to the lens-distortion processing at an (n+2)-th timing ofVsync (S86).

In this manner, the (n−1)-th CG image is generated in the rendering, the(n−1)-th CG image is superimposed on the (n−1)-th camera image and onthe n-th camera image, and the post-processing is performed. Since thepost-processing is performed at a frequency which is two times higherthan the frequency of the rendering and which is equal to the frame rateof the camera, smooth images are generated.

Note that although two camera images are superimposed on the same CGimage rendered once and the post-processing is performed on theresultant superimposed image in the explanation given above, a pluralityof camera images may be superimposed on a CG image rendered once and thepost-processing may be performed multiple times on the resultantsuperimposed images if the render takes a longer time.

In the explanation given above, the reverse reprojection is not appliedto a camera image when a rendering result CG image is superimposed onthe first camera image, and the reverse reprojection is applied tosecond and subsequent camera images when the same CG image issuperimposed on the second and subsequent camera images. However, sincethe rendering takes a long time, preferably a latest camera image isacquired immediately before the post-processing. Accordingly, adifference occurs between the timestamp of a viewpoint ofthree-dimensional graphics used for the rendering and the timestamp of acamera image on which the three-dimensional graphics are superimposed.In such a case, even when a CG image is superimposed on the first cameraimage, the reverse reprojection may be applied to the camera image, andthen the CG image may be superimposed thereon so that there will not bea difference between the two timestamps.

The reverse reprojection is performed to make the timestamp of aviewpoint of three-dimensional graphics match the timestamp of a cameraimage used at the time of the post-processing, and IMU data acquired ata time point between the two timestamps is used for computing anorientation difference to be applied in the reverse reprojection.

Note that IMU data is always acquired from an inertial measurement unit,and all the IMU data of intervals required for the reprojection can beused to predict the orientation. The cycle at which the IMU data isacquired is equal to or shorter than 1 millisecond, and is shorter thanthe interval of Vsync. It is sufficient to perform linear interpolationfor IMU data corresponding to time of prediction during intervals inwhich there is insufficiency of IMU data.

As mentioned above, the image generating apparatus 200 of the presentembodiment superimposes a plurality of camera images on a CG image whichis a result of the rendering performed once, and performs thepost-processing multiple times. Accordingly, the apparent frame rateincreases to the frame rate of camera images, and smooth and naturalaugmented-reality images can be generated.

Although the post-processing is performed on augmented-reality images inwhich CG images are superimposed on camera images at a frequency higherthan the frequency of the rendering to generate smooth augmented-realityimages in the embodiment explained above, this method can be applied notonly to tracking of a head-mount display, but also to cases where theangle of a virtual camera typically used for rendering changes, andsimilar effects can be attained in such cases. For example, in a casewhere virtual objects are rendered and effects are displayed on the nearside while a moving image is being reproduced on the background, theapparent quality can be improved by anti-aliasing or noise reduction.

In addition, the post-processing may be performed at a frequency higherthan the frequency of the rendering for multi-layer rendering. Forexample, objects that are located nearby and move a lot are rendered ata high frame rate, objects that are located far away and move less arerendered at a low frame rate, both the objects are synthesized, and thepost-processing is performed thereon. The apparent quality can beimproved by increasing the frequency of the post-processing.

The present invention has been explained on the basis of the embodimentthus far. It should be understood by those skilled in the art that theembodiment is illustrated as an example, that various variants arepossible for combinations of constituent elements and processingprocesses of the embodiment, and that those variants also fall withinthe scope of the present invention.

REFERENCE SIGNS LIST

10 Control unit, 20 Input interface, 30 Output interface, 32 Displaypanel, 40 Communication control unit, 42 Network adapter, 44 Antenna, 50Storage unit, 64 Orientation sensor, 70 External input/output terminalinterface, 72 External memory, 80 Camera unit, 100 Head-mount display,200 Image generating apparatus, 210 Position/orientation acquiring unit,220 Viewpoint/line-of-sight setting unit, 230 Image generating unit, 232Rendering unit, 234 AR superimposing unit, 236 Post-processing unit, 238Reverse-reprojection unit, 240 Reprojection unit, 242 Distortionprocessing unit, 250 Image-signal processing unit, 260 Image storageunit, 280 HDMI transmitting/receiving unit, 300 Interface

INDUSTRIAL APPLICABILITY

The present invention can be applied to the field of image generation.

1. (canceled)
 2. An image generating apparatus comprising: a renderingunit that renders an object in a virtual space to generate a computergraphics image; a reverse-reprojection unit that reverse-converts acaptured image of a reality space such that a viewpoint position or aline-of-sight direction of the captured image matches a viewpointposition or a line-of-sight direction at a time point at which therendering unit has generated the computer graphics image; asuperimposing unit that superimposes the computer graphics image on thecaptured image having been subjected to the reverse-conversion by thereverse-reprojection unit, to generate an augmented-reality image; and apost-processing unit that performs post-processing on theaugmented-reality image, wherein the superimposing unit superimposes, onthe same computer graphics image, a plurality of the captured imagesprovided at a frame rate higher than a frame rate of the computergraphics image generated by the rendering unit, to generate theaugmented-reality image.
 3. The image generating apparatus according toclaim 2, further comprising: a reprojection unit that converts theaugmented-reality image having been subjected to the post-processing,such that a viewpoint position or a line-of-sight direction of theaugmented-reality image matches a new viewpoint position or a newline-of-sight direction.
 4. The image generating apparatus according toclaim 3, wherein the superimposing unit superimposes the computergraphics image on each of a plurality of the captured images afterhaving been subjected to the reverse-conversion by thereverse-reprojection unit, to generate the augmented-reality image. 5.The image generating apparatus according to claim 3, wherein thesuperimposing unit superimposes the computer graphics image on the firstcaptured image to generate the first augmented-reality image, andsuperimposes the computer graphics image on the second and subsequentcaptured images after having been subjected to the reverse-conversion bythe reverse-reprojection unit, to generate the second and subsequentaugmented-reality images.
 6. An image generation method comprising:rendering an object in a virtual space to generate a computer graphicsimage; reverse-converting a captured image of a reality space such thata viewpoint position or a line-of-sight direction of the captured imagematches a viewpoint position or a line-of-sight direction at a timepoint at which the computer graphics image has been generated in therendering; superimposing the computer graphics image on the capturedimage having been subjected to the reverse-conversion in thereverse-reprojection, to generate an augmented-reality image; andperforming post-processing on the augmented-reality image, wherein inthe superimposing, a plurality of the captured images provided at aframe rate higher than a frame rate of the computer graphics imagegenerated in the rendering are superimposed on the same computergraphics image to generate the augmented-reality image.
 7. Anon-transitory, computer readable recording medium containing a computerprogram, which when executed by a computer, causes the computer to carryout actions, comprising: rendering an object in a virtual space togenerate a computer graphics image; reverse-converting a captured imageof a reality space such that a viewpoint position or a line-of-sightdirection of the captured image matches a viewpoint position or aline-of-sight direction at a time point at which the computer graphicsimage has been generated by the rendering; superimposing the computergraphics image on the captured image having been subjected to thereverse-conversion by the reverse-reprojection, to generate anaugmented-reality image; and performing post-processing on theaugmented-reality image, wherein by the superimposing, a plurality ofthe captured images provided at a frame rate higher than a frame rate ofthe computer graphics image generated by the rendering are superimposedon the same computer graphics image to generate the augmented-realityimage.